SEQUESTERING CO2 IN HOUSTON - ou.edu€¦ · Separation Methods ... CO2 1 atm 580 C NaOH Heat...
Transcript of SEQUESTERING CO2 IN HOUSTON - ou.edu€¦ · Separation Methods ... CO2 1 atm 580 C NaOH Heat...
Final PresentationFinal PresentationGroup 8Group 8
Tuesday, April 29, 2003Tuesday, April 29, 2003
Sequestering COSequestering CO22
Lisa CoxLisa CoxMeghan ForesterMeghan Forester
Jacob HeddenJacob Hedden
Jennifer ScrogginJennifer ScrogginThomas SmithThomas Smith
OverviewOverview
Introduction to SequestrationIntroduction to SequestrationSeparation MethodsSeparation MethodsTransportation NetworkTransportation NetworkSequestration MethodsSequestration MethodsMathematical ModelMathematical ModelResults and RecommendationsResults and Recommendations
What is sequestration?What is sequestration?
Storage to reduce atmospheric levels Storage to reduce atmospheric levels of COof CO2 2
Four Methods of SequestrationFour Methods of Sequestration–– GeologicGeologic–– OceanOcean–– TerrestrialTerrestrial–– MineralMineral
MotivationMotivation
PostPost--Industrial RevolutionIndustrial Revolution–– COCO22 levels steady increaselevels steady increase
Global Warming/Greenhouse EffectGlobal Warming/Greenhouse Effect–– Greenhouse gases (i.e. COGreenhouse gases (i.e. CO22))
Kyoto ProtocolKyoto Protocol–– Possible ratification by U.S.Possible ratification by U.S.–– Requires 12% reduction in CORequires 12% reduction in CO22
emissions by 2010emissions by 2010
Climate Stewardship Act of 2003Climate Stewardship Act of 2003
Power plant emissionsPower plant emissions
Fossil fuel combustionFossil fuel combustion–– 97% of all CO97% of all CO22 emissionsemissions–– Power plants are major sites of fossil Power plants are major sites of fossil
fuel combustionfuel combustion
COCO22 emissions in U.S.emissions in U.S.–– 22ndnd highest in Greenhouse Gas highest in Greenhouse Gas
emissions per capita in 1998emissions per capita in 1998–– Major cities are highest contributorsMajor cities are highest contributors
Houston, TexasHouston, Texas
Reducing COReducing CO22 in Harris Countyin Harris County
Large power plants Large power plants Proximity of depleted hydrocarbon Proximity of depleted hydrocarbon reservoirs, brine aquifers, and the reservoirs, brine aquifers, and the oceanoceanSeven power plants in Harris CountySeven power plants in Harris County–– emitted 5.3 million tons of COemitted 5.3 million tons of CO22 in 2000in 2000
Harris County Power PlantsHarris County Power Plants
Power Plant SchematicPower Plant SchematicBurning of natural Burning of natural gas in airgas in airHeat generation to Heat generation to make steammake steamSteam driven Steam driven turbine for turbine for distribution of distribution of electrical powerelectrical powerReaction products Reaction products emitted to emitted to atmosphereatmosphere
Project ObjectivesProject Objectives
Governmental PerspectiveGovernmental Perspective–– Recent legislation to decrease carbon Recent legislation to decrease carbon
dioxide emissionsdioxide emissions
Determine reasonable emissions Determine reasonable emissions reduction requirementsreduction requirements–– Minimize electricity cost increaseMinimize electricity cost increase
Why Separate?Why Separate?
Flue gas composition Flue gas composition ~ 4 wt% CO~ 4 wt% CO22
High flow ratesHigh flow rates~ 0.5~ 0.5--57 million tons/year57 million tons/year
Sequestration pressureSequestration pressure~ 1000 ~ 1000 psiapsia
Methods of SeparationMethods of Separation
Absorption in a packed towerAbsorption in a packed towerAdsorption on solidsAdsorption on solidsRefrigerationRefrigeration
OxygenOxygen--enriched fuel firingenriched fuel firingMembrane SeparationMembrane Separation
Reaction with Calcium HydroxideReaction with Calcium Hydroxide
Absorption/StrippingAbsorption/Stripping
MonoethanolamineMonoethanolamine solventsolvent–– High solubility of COHigh solubility of CO22 in MEAin MEA
Random packing (polyethylene rings)Random packing (polyethylene rings)–– Increased contact area between flue gas Increased contact area between flue gas
and solventand solvent
Separation with heat after absorptionSeparation with heat after absorption–– 85% CO85% CO22, 15% H, 15% H2200
PFDPFD
AbsorberScrubberFlue Gas
1 atm356 F
Heat Exchanger 1Outlet Temp: 90 F
Regenerator
Rich MEA136 F Heat Exchanger 2
Outlet Temp: 200 F
SaturatedSteam
Clean Flue GasExhaust
Heat Exchanger 3Outlet Temp: 90 F
Isothermal Flash35 F
98% CO21 atm
H20
Centrifugal Pump2000 hp
30% MEA in H20240 F
H20
MEA
Mixer
Compressor:20 psia
CO2 + H201 atm120 F
EconomicsEconomics
Commercially available unitsCommercially available units–– WittemannWittemann Carbon Dioxide EquipmentCarbon Dioxide Equipment–– Includes all componentsIncludes all components
Capital CostCapital Cost–– 250250--15,000 kg/hr flue gas15,000 kg/hr flue gas–– $0.5$0.5--$50 million/unit$50 million/unit
Operating CostOperating Cost–– $0.17/kg flue gas$0.17/kg flue gas
Calcium HydroxideCalcium Hydroxide
CarbonationCarbonation
CalcinationCalcination
SlakingSlaking
molkJHOHCaCOOHCaCO R 179)( 2322 −=∆+→+
molkJHCOCaOCaCO R
C 19.42580
3 =∆+ →o
molkJHOHCaOHCaO R 9.63)( 22 −=∆→+
AssumptionsAssumptions
High rate of reaction under alkaline High rate of reaction under alkaline conditions (pH>10)conditions (pH>10)–– Addition of Addition of NaOHNaOH
Mass transfer limitingMass transfer limiting–– Diffusion of CODiffusion of CO22 in Ca(OH)in Ca(OH)22 solutionsolution
Modeling the systemModeling the system
Flanking viewFlanking view Top viewTop view
Reactor DesignReactor Design
Gas Gas SpargerSparger–– Commercially available (Mott Corp)Commercially available (Mott Corp)–– Even distribution of bubblesEven distribution of bubbles–– 2 mm diameter bubbles2 mm diameter bubbles
CrossCross--sectional areasectional area–– Determined by throughputDetermined by throughput–– Volumetric flow rate estimated by IGLVolumetric flow rate estimated by IGL
Compressibility factor=0.9989Compressibility factor=0.9989
HeightHeight–– Determined by rate of mass transferDetermined by rate of mass transfer
P&IDP&ID
Combustion ChamberFlame Temperature: 834 CCH4
AIR
Calcium HydroxideReactor
Calcium HydroxideRegenerator
Flue Gas1 atm480 F
H20CO21 atm580 C
NaOH
Heat ExchangerOutlet Flue Gas:
298 K
LA
pHT
pHC
LC
Flue Gas:0% CO2
CT
CC
Calcium HydroxideReactor
Flue Gas0% CO2
Flue Gas0% CO2
Calcium HydroxideReactor
Pressure Vessel50 psia
Holding Tankfor ExcessCa(OH)2Solution
S-14
S-15
PTPC
CO2 forSequestration
EconomicsEconomics
Capital cost considerationsCapital cost considerations–– Heat ExchangerHeat Exchanger–– ReactorReactor–– Calcium HydroxideCalcium Hydroxide–– CalcinerCalciner–– Gas Gas SpargerSparger
Operating CostOperating Cost–– Hot/Cold UtilitiesHot/Cold Utilities
Capital CostCapital Cost
0.000.501.001.502.002.503.003.50
0.E+00 1.E+06 2.E+06 3.E+06 4.E+06 5.E+06 6.E+06
Capacity (kg/hr)
Cap
ital C
ost
(Mill
ion
$)
Capital Cost ($)=331,000+0.454*Capacity (kg/hr)
Operating CostOperating Cost
Energy BalanceEnergy Balance
Final Operating CostFinal Operating Cost–– $0.0047/kg flue gas$0.0047/kg flue gas
HnQ ∆≈
OxygenOxygen--Enriched Fuel FiringEnriched Fuel Firing
Alternative to separationAlternative to separationAir SeparationAir SeparationCombustion in pure oxygenCombustion in pure oxygenDrawbacksDrawbacks–– High capitalHigh capital–– High operating costsHigh operating costs–– Retrofit to existing equipmentRetrofit to existing equipment
Transportation NetworkTransportation Network
Required for delivery of CORequired for delivery of CO22 to to collection pointcollection point–– “Sam “Sam BertronBertron” power plant” power plant
Compressed at site of separationCompressed at site of separationCombined and liquefied at collection Combined and liquefied at collection pointpoint–– Compressed for sequestration (1300 Compressed for sequestration (1300
psiapsia))–– Liquefied with coolingLiquefied with cooling
Transportation SchematicTransportation Schematic
Capital CostCapital Cost–– $9.02$9.02--$9.35 million$9.35 million–– 8,4008,400--131,000 kg/hr131,000 kg/hr
Operating CostOperating Cost–– $.83/ton CO$.83/ton CO22
Transportation Capital CostTransportation Capital Cost
9
9.05
9.1
9.15
9.2
9.25
9.3
0 20000 40000 60000 80000 100000 120000
Flow rate (kg/hr)
Cap
ital C
ost (
Mill
ion
$)
Capital Cost ($)=9,000,000+2.67*Capacity (kg/hr)
Final Piping NetworkFinal Piping Network
Ocean SequestrationOcean Sequestration
Ocean capacityOcean capacity–– Largest capacity sequestration methodLargest capacity sequestration method–– Est. 1.4×10Est. 1.4×101212 to 2×10to 2×101616 metric tonsmetric tons
InjectionInjection–– Various depthsVarious depths–– Liquid COLiquid CO22
OverviewOverview
Formation of clathrate hydratesFormation of clathrate hydrates–– Densities change with injection depthDensities change with injection depth–– Effects longEffects long--term storage potentialterm storage potential
Ocean floor poolingHigh densityDeep (≥ 2700 m)
CO2 resurfacingLow densityShallow (< 2700 m)
ImplicationsClathrate HydrateInjection Depth
ComplicationsComplications
Rapid injection decreases pHRapid injection decreases pH–– Considerable effect on ocean Considerable effect on ocean
environmentenvironmentLegal restrictionsLegal restrictions–– COCO22 considered an industrial wasteconsidered an industrial wasteTransportation costsTransportation costs–– Economically prohibitiveEconomically prohibitive–– LPG tankersLPG tankers
$650 million$650 million–– Rigid PipelineRigid Pipeline
$16 million/km$16 million/km
Transportation Costs Transportation Costs
6501312.26398516001211.043586.50.9500109.8131880.845098.582789.50.740087.3623910.635076.131992.50.525054.9015940.420043.681195.50.315032.457970.210021.23398.50.1
Cost (Million
$)
Minimum # Tankers
Required # Tankers
(1Tanker /325MW)
Power Requirements
Fraction Sequestered
ConclusionsConclusions
Economics unfavorableEconomics unfavorableSafety issues for ocean ecosystemSafety issues for ocean ecosystemLegal constraints on waste disposal Legal constraints on waste disposal in oceanin oceanOther sequestration options existOther sequestration options exist
Geologic Sequestration Geologic Sequestration Brine AquifersBrine Aquifers
Largest estimated geologic COLargest estimated geologic CO22sequestration capacity (est. 500 billion sequestration capacity (est. 500 billion tons COtons CO2 2 globally)globally)
Most aquifers are easily accessible from Most aquifers are easily accessible from COCO22 generation sources and many are generation sources and many are already utilized for waste disposalalready utilized for waste disposal
Current studies are investigating “sealing” Current studies are investigating “sealing” layer rock properties and the possibility of layer rock properties and the possibility of brine displacement which could brine displacement which could contaminate potable watercontaminate potable water
Brine Aquifers Brine Aquifers –– Process OverviewProcess Overview
Considerations:Considerations:NonNon--hydrocarbon hydrocarbon producing injection producing injection intervalintervalSupercritical COSupercritical CO2 2 desired for desired for injectioninjection“Sealing” boundary “Sealing” boundary layerslayers Source: Engineering & Economic Assessment of
Carbon Dioxide Sequestration in Saline Formations
Brine Aquifers Brine Aquifers –– Harris CountyHarris CountyFrio Formation is Frio Formation is brinebrine--bearing bearing sandstone sandstone –– shale shale sequencesequence2828––35% porosity35% porosityAnahuac Formation Anahuac Formation provides thick clay provides thick clay wedge sealwedge sealEst. capacity of Est. capacity of 230230--390 Billion 390 Billion tons COtons CO22
To EORStorage Tanks
Compressed CO2 sent topre-existing injection wells
located 12 milesfrom collection point
Capital Investment for Brine AquifersCapital Investment for Brine Aquifers
70.0
70.5
71.0
71.5
72.0
72.5
0.E+00 2.E+04 4.E+04 6.E+04 8.E+04 1.E+05
Capacity (kg/hr)
Cap
ital I
nves
tmen
t (M
illio
n $)
Capital Cost ($) =
70,000,000 + 27.75*Capacity (kg/hr)
Geologic Sequestration Geologic Sequestration EOREOR
32 Million tons CO32 Million tons CO22 utilized annually utilized annually in USin USInjection technology well developedInjection technology well developedCurrent research projects monitoring Current research projects monitoring injected COinjected CO22 flow patterns to better flow patterns to better assess true sequestration capabilityassess true sequestration capabilityProfit potential from COProfit potential from CO22 sales could sales could help offset separation and help offset separation and transportation coststransportation costs
EOR EOR –– Process OverviewProcess Overview
COCO22 injected into injected into depleted oil depleted oil reservoirsreservoirsReservoir pressure Reservoir pressure increasesincreasesCrude oil viscosity Crude oil viscosity decreasesdecreasesAs a result, As a result, recovery factors recovery factors increase by ~10%increase by ~10%
CO2Crude Oil
Source: http://www.netl.doe.gov/publications/proceedings/01/carbon_seq/2a4.pdf
EOR Option for Harris CountyEOR Option for Harris CountyCapacity AssessmentCapacity Assessment
51 oil wells51 oil wellsAverage well Average well conditions:conditions:40 acres surface area40 acres surface area37 feet pay height37 feet pay height3,100 feet depth3,100 feet depth115 115 °°F & 1364 F & 1364 psipsiAPI gravity 29API gravity 29°°Assumptions:Assumptions:15% porosity15% porosity45% water saturation45% water saturation
Concentration of Oil Wells in Harris County
EOR Option for Harris CountyEOR Option for Harris CountyEstimated Oil in Place:Estimated Oil in Place:48 Million 48 Million bblsbbls originallyoriginally34 Million 34 Million bblsbbls currently remainingcurrently remaining29 Million 29 Million bblsbbls ultimately unrecoverableultimately unrecoverable
COCO22 solubility at reservoir conditions:solubility at reservoir conditions:780 780 scfscf/bbl in crude oil/bbl in crude oil160 160 scfscf/bbl in water/bbl in water
Sequestration Capacity:Sequestration Capacity:1.7 Million tons CO1.7 Million tons CO22 soluble in unrecoverable soluble in unrecoverable crude oil & formation watercrude oil & formation water
EOR EOR Specifications & ParametersSpecifications & Parameters
Additional Fixed Additional Fixed Capital Investment Capital Investment of $300,000of $300,000
Selling Price of COSelling Price of CO22
$35/ton$35/ton
Sent to EORStorage Tanks
To Brine Aquifers
Planning ModelPlanning Model
Linear ModelLinear ModelGeneral Algebraic Modeling System General Algebraic Modeling System (GAMS) Interface(GAMS) InterfaceUses CPLEX to solve linear modelUses CPLEX to solve linear model–– Material BalancesMaterial Balances–– Cost EquationsCost Equations–– Emissions TradingEmissions Trading–– Enhanced Oil RecoveryEnhanced Oil Recovery
Flow Sheet for Model Flow Sheet for Model
EnhancedOil Recovery
‘EOR’
BrineAquifers‘Aquifers’
SequestrationMethods:
CollectionPoint:
CollectionPoint
W’EOR’
Separation Methods:
Plants: 1
A B
Vent to atmosphere
7
A B
2
A B
3
A B
4
A B
5
A B
6
A B
Di Fi
W’Aquifers’ ∑=j
jWCE
( )∑ +=j
jj FDCE
ii
ii
BlF
AhD
⋅=
⋅=
XE
AVYE
ii
iii
≤
⋅+⋅=
∑001.0
iiii VBAQ
BalanceMaterial
++=
Cost EquationsCost Equations
Equipment CostsEquipment CostsOperating CostsOperating CostsTransportation CostsTransportation CostsTotal Capital InvestmentTotal Capital InvestmentProfit from selling COProfit from selling CO22
Profit from emissions tradingProfit from emissions tradingTotal Annualized CostTotal Annualized Cost
Equipment CostsEquipment Costs
Each separation and sequestration Each separation and sequestration method has a binary variablemethod has a binary variable–– 1 if used1 if used–– 0 if not used0 if not used
Equipment costs are assumed to be Equipment costs are assumed to be linear with capacitylinear with capacity
[ ] [ ]Cost VariableCapacity CostFixed
VariableBinary
Cost
Equipment×+
×
=
Operating CostsOperating Costs
IncludesIncludes–– Utility costUtility cost–– Raw materialsRaw materials
Units of operating cost slope are Units of operating cost slope are $/(kg/hr)$/(kg/hr)
×
=
Slope
OperatingRateFlow
Cost
Operating
Transportation CostsTransportation Costs
Similar to operating costSimilar to operating costDepends on the distance to transportDepends on the distance to transport
Transportation cost slopeTransportation cost slope–– $/((Kg/hr) mile)$/((Kg/hr) mile)
×
×
=
Slope
tionTransportaDistance
SiteRate Flow
CO
CosttionTransporta 2
Profit from Selling COProfit from Selling CO22
Sell for EORSell for EORProfit = Flow rate to EOR (Price of Profit = Flow rate to EOR (Price of COCO22))Can only sell a certain amount for Can only sell a certain amount for this purposethis purpose
kg/hr 400,17 W t,'EOR' ≤
Emissions TradingEmissions Trading
2 Categories of Emissions Trading 2 Categories of Emissions Trading (ET)(ET)–– Internal : Among 7 power plants in Internal : Among 7 power plants in
Harris CountyHarris County–– External : If Harris County plants External : If Harris County plants
exceed required emissions reductions, exceed required emissions reductions, excess units of reduction can be sold for excess units of reduction can be sold for profitprofit
Emissions TradingEmissions Trading
Incentive to capture and sequester Incentive to capture and sequester more COmore CO22
Helps to offset costs to electricity Helps to offset costs to electricity consumersconsumersTerminologyTerminology–– Emissions Reduction Credit (ERC)Emissions Reduction Credit (ERC)–– 1 ERC is 1 ton of CO1 ERC is 1 ton of CO22 sequestered sequestered
beyond required reductionbeyond required reduction
Emissions TradingEmissions Trading
No official government CONo official government CO22 ET ET programprogramPricing EstimatesPricing Estimates–– Wharton Econometric Forecasting Wharton Econometric Forecasting
AssociatesAssociates–– $54/ERC$54/ERC–– Will vary over time with same trend as Will vary over time with same trend as
electricity priceselectricity prices
Emissions TradingEmissions Trading
Voluntary ProgramsVoluntary Programs–– Chicago Climate ExchangeChicago Climate Exchange
Equation for modelEquation for model–– ET within network in Harris county ET within network in Harris county
generates no profitgenerates no profit–– Externally, profit can be generatedExternally, profit can be generated–– Profit = Price per ERC (Number of Profit = Price per ERC (Number of ERCsERCs))
Total Annualized CostTotal Annualized Cost
–– Translation to electricity price increaseTranslation to electricity price increaseDivide by the total capacity of all of the Divide by the total capacity of all of the plants in the networkplants in the networkResult: $/kWh needed for the sequestration Result: $/kWh needed for the sequestration to pay for itselfto pay for itself
–– Objective of mathematical model: Objective of mathematical model: minimize cost increase to electricity minimize cost increase to electricity consumersconsumers
Model Results Model Results -- SummarySummary
15% Reduction over 10 years (1.5% 15% Reduction over 10 years (1.5% per year)per year)Calcium Hydroxide separation in all Calcium Hydroxide separation in all casescasesDepending % emissions reduction, Depending % emissions reduction, different plants will separate and different plants will separate and sequester COsequester CO22
Use Brine Aquifers to sequesterUse Brine Aquifers to sequester
Model Results Model Results –– Electricity Cost Electricity Cost ScenariosScenarios
0.06
0.062
0.064
0.066
0.068
0.07
0.072
0.074
0 2 4 6 8 10 12
Year
Cos
t ($/
kWh)
0% Reduction 15% Reduction 35% Reduction 50% Reduction
Model Results Model Results –– Emissions Emissions Reductions (Total Annualized Cost)Reductions (Total Annualized Cost)
0
50
100
150
200
250
300
350
0 2 4 6 8 10 12
year
Tota
l Ann
ualiz
ed C
ost (
Mill
ions
$/y
r)
15% Reduction 35% Reduction 50% Reduction
Model Results Model Results –– Electricity Price Electricity Price due to changing Ca(OH)due to changing Ca(OH)22 CostCost
0.06
0.062
0.064
0.066
0.068
0.07
0 2 4 6 8 10 12
year
Elec
tric
ity P
rice
($/k
Wh)
-30% Error -20% Error -10% Error 10% Error 20% Error 30% Error
Base Estimate
Model Results Model Results –– Total Annualized Total Annualized Cost for changing Ca(OH)Cost for changing Ca(OH)22 CostCost
0
20
40
60
80
100
120
140
160
0 2 4 6 8 10 12
year
Tota
l Ann
ualiz
ed C
ost (
Mill
ions
$/
yr)
-30% Error -20% Error -10% Error Base Estimate10% Error 20% Error 30% Error
Model Results Model Results –– Electricity Price for Electricity Price for Transportation Cost VariationTransportation Cost Variation
0.06
0.062
0.064
0.066
0.068
0.07
0 2 4 6 8 10 12
year
Elec
tric
ity P
rice
($/k
Wh)
-30% Error -10% Error 10% Error 30% Error
Base Estimate
Model Results Model Results –– Total Annualized Total Annualized Cost for Transportation VariationCost for Transportation Variation
0
20
40
60
80
100
120
140
0 2 4 6 8 10 12
year
Tota
l Ann
ualiz
ed C
ost (
$x10
6 /yr)
-30% Error -10% Error Base Estimate10% Error 30% Error
Model Results Model Results –– Aquifers Aquifers Electricity Price SensitivityElectricity Price Sensitivity
0.06
0.062
0.064
0.066
0.068
0.07
0 2 4 6 8 10 12
Year of Project
New
Ele
ctric
ity P
rice
($/k
Wh)
-30% Error -20% Error -10% Error 10% Error 20% Error 30% Error
Base Estimate
Model Results Model Results –– Aquifers Total Aquifers Total Annualized Cost SensitivityAnnualized Cost Sensitivity
0
20
40
60
80
100
120
140
0 2 4 6 8 10 12
Year of Project
Tota
l Ann
ualiz
ed C
ost
(Mill
ions
$/y
r)
-30% Error -20% Error -10% Error 10% Error20% Error 30% Error Base Estimate
Model Results Model Results –– Price Sensitivity Price Sensitivity for ERCfor ERC
0.06
0.062
0.064
0.066
0.068
0.07
0 2 4 6 8 10 12
Year
Pric
e of
Ele
ctric
ity ($
/kW
h)
-30% -20% -10% 10% 20% 30%
Base Estimate
Model Results Model Results –– Price Sensitivity Price Sensitivity for ERCfor ERC
0
20
40
60
80
100
120
140
0 2 4 6 8 10
Year
Tota
l Ann
ualiz
ed C
ost
(Mill
ions
of $
/yr)
-30% Error -20% Error -10% Error 10% Error20% Error 30% Error Base Estimate
Model ResultsModel Results
Price Sensitivity of COPrice Sensitivity of CO22–– In order to use EOR some capital In order to use EOR some capital
investment is requiredinvestment is required–– Current price of COCurrent price of CO22 $35/ton $35/ton
($0.039/kg)($0.039/kg)–– EOR is not a viable option in the 30% EOR is not a viable option in the 30%
deviation range for the price of COdeviation range for the price of CO22
–– In order for EOR to be used, the price of In order for EOR to be used, the price of COCO22 would have to be $370/ton would have to be $370/ton ($0.41/kg)($0.41/kg)
This is extremely unlikelyThis is extremely unlikelyDemonstrated by Stochastic ModelDemonstrated by Stochastic Model
Risk AnalysisRisk AnalysisIncorporate risk into mathematical Incorporate risk into mathematical modelmodelVariables with the greatest amount Variables with the greatest amount of riskof risk–– Price of ElectricityPrice of Electricity
Forecasting by Energy Information Forecasting by Energy Information AdministrationAdministration
–– Price of COPrice of CO22
–– Price of ERCPrice of ERC–– Price of COPrice of CO22 and ERC will vary with and ERC will vary with
same trend as electricity costsame trend as electricity cost
Forecasting of Electricity PricesForecasting of Electricity Prices
6.2
6.4
6.6
6.8
7
7.2
7.4
1995 2005 2015 2025
Year
Cos
t ($x
10-2/ k
Wh)
Source: Energy Information Administrationhttp://www.eia.doe.gov/oiaf/aeo/aeotab_1.htm
Forecasting of COForecasting of CO22 PricesPrices
20222426283032343638
0 2 4 6 8 10Year of Project
Cos
t ($/
ton)
Forecasting of ERC PricesForecasting of ERC Prices
30
35
40
45
50
55
60
0 2 4 6 8 10 12
Year of Project
Pric
e of
ER
C ($
)
Conversion to Stochastic ModelConversion to Stochastic Model
Obtain average values for each year Obtain average values for each year for risky variablesfor risky variablesObtain standard deviation for each Obtain standard deviation for each yearyearAdd scenarios to the modelAdd scenarios to the model–– Assume normal distribution with 30 Assume normal distribution with 30
scenariosscenarios–– Generate values for variables within Generate values for variables within
modelmodel
Conversion to Stochastic ModelConversion to Stochastic Model
Change objective functionChange objective function–– Minimize expected cost increase of Minimize expected cost increase of
electricityelectricity–– Expected Value:Expected Value:
The stochastic model will tell us The stochastic model will tell us “Here and Now” decisions“Here and Now” decisions–– What should we install now to have the What should we install now to have the
best result for all of the possible best result for all of the possible scenariosscenarios
{ } xxPr)x(E ⋅=
Results of Stochastic Model Results of Stochastic Model –– Price HistogramPrice Histogram
0
0.05
0.1
0.15
0.2
0.25
0.3
0.002 0.004 0.006 0.008 0.01 0.012 0.014 0.016 0.018 0.02 0.022 0.024 0.026
Electricity Price Increase ($/kWh)
Prob
abili
ty
Risk CurveRisk Curve
00.10.20.30.40.50.60.70.80.9
1
0 0.005 0.01 0.015 0.02 0.025 0.03
Price Increase of Electricity ($/kWh)
Ris
k
RecommendationsRecommendations
Stochastic model doesn’t warrant Stochastic model doesn’t warrant any major changes over any major changes over deterministic modeldeterministic model–– 15% Reduction over 10 years15% Reduction over 10 years–– Calcium Hydroxide separation in all Calcium Hydroxide separation in all
casescases–– Depending % emissions reduction, Depending % emissions reduction,
different plants will separate and different plants will separate and sequester COsequester CO22
–– Use Brine Aquifers to sequesterUse Brine Aquifers to sequester
RecommendationsRecommendationsStochastic model recommends different Stochastic model recommends different capacities than deterministic modelcapacities than deterministic model
Deterministic Model Stochastic Model
1 Sam Bertron Sam Bertron and Deepwater
2 Webster Greens Bayou, Hiram Clarke, and Webster
3Increase Capacity of Sam
Bertron and add Hiram Clarke
Increase Capacity of Greens Bayou
4 Increase Capacity of Sam Bertron
Increase Capacity of Greens Bayou
5 TH Wharton No additions necessary
6 No additions necessary Increase Capacity of Greens Bayou
7 No additions necessary No additions necessary8 Greens Bayou No additions necessary
9 Deepwater Increase Capacity of Sam Bertron
10 No additions necessary Increase Capacity of Sam Bertron
Plant where Ca(OH)2 System InstalledYear